References to my papers exist in the following publications. The data comes from Google Scholar, after suitable processing (removal of self-citations, etc).

Publications in Refereed Journals

[J6]Alexandros Papageorgiou, Nikos Platis, Triangular mesh simplification on the GPU, The Visual Computer, 31(2), pp. 235–244 (2014) (Also in NASAGEM Geometry Processing Workshop, Computer Graphics International 2013).
  1. Muhammad Naveed Akhtar, Muhammad Hanif Durad, Anila Usman, Muhammad Abid Mughal, Efficient Memory Access Patterns for Solving 3D Laplace Equation on GPU, Iranian Journal of Science and Technology, Transactions A: Science (2016).
  2. Hyunho Lee, Min-Ho Kyung, Parallel mesh simplification using embedded tree collapsing, The Visual Computer, 32(6), pp. 967–976 (2016).
  3. Nuttapong Chentanez, Matthias Müller, Miles Macklin, GPU accelerated grid-free surface tracking, Computers & Graphics, 57, pp. 1–11 (2016).
  4. Thomas Odaker, Adaptive Vereinfachung von Dreiecksnetzen in Echtzeit [Adaptive simplification of triangular meshes in real time], PhD Thesis, Fakultät für Mathematik, Informatik und Statistik, Ludwig-Maximilians-Universität München (2016).
  5. Thomas Odaker, Dieter Kranzlmueller, Jens Volkert, GPU-Accelerated Triangle Mesh Simplification Using Parallel Vertex Removal, International Journal of Computer, Electrical, Automation, Control and Information Engineering, 10(1), pp. 160–166 (2016).
  6. Thomas Odaker, Dieter Kranzlmueller, Jens Volkert, View-dependent Simplification using Parallel Half Edge Collapses, Proceedings of WSCG 2015, pp. 63–72 (2015).
  7. Xiaodong Che, Yu Niu, Bin Shui, Jianbo Fu, Guangzheng Fei, Prashant Goswami, Yanci Zhang, A novel simulation framework based on information asymmetry to evaluate evacuation plan, The Visual Computer, 31(6–8), pp. 853–861 (2015).
  8. Iván Yerko Rojas Hernández, Optimization and parallelization of an algorithm for the generation of skeletons from geometric meshes applied in biological structures [Optimización y paralelización de un algoritmo de generación de Skeletons a partir de mallas geométricas aplicado a estructuras biológicas], BEng Thesis, Departamento De Ciencias de la Computatión, Univesidad De Chile (2014)
  9. V.I. Gonakhchyan, Survey of polygonal surface simplification algorithms on GPU, Proceedings of the Institute for System Programming of RAS, 26(2), pp. 159–174 (2014).
[J5]Andreas Papatheodorou, Nikos Platis, Airline Deregulation, Market Conduct and Tort Liability, Rivista di Politica Economica, I-II 2007, pp. 221–242 (2008).
  1. Adam Pawlicz, Economic Rationale for Licensing Tour Guides in Poland, Tourism in Southern and Eastern Europe, pp. 295–304 (2013).
  2. Guido Candela, Paolo Figini, The Economics of Tourism Destinations, Springer (2012).
[J4]Nikos Platis, Theoharis Theoharis, Progressive Hulls for Intersection Applications, Computer Graphics Forum, 22(2), σελ. 107–116 (2003).
  1. Andre Gaschler, Efficient Geometric Predicates for Integrated Task and Motion Planning, PhD Thesis, Technische Universität München, Germany (2016).
  2. Andre Gaschler, Quirin Fischer, Alois Knoll, The Bounding Mesh Algorithm, Technical Report TUM-I1522, Technische Universität München, Germany (2015).
  3. Leonardo Sacht, Etienne Vouga, Alec Jacobson, Nested Cages, ACM Transactions on Graphics, 34(6) (2015).
  4. Liu Tao, Feng Jie-Qing, Chen Xue, Cage Generation Based on Visual Hull, Journal of Software, 24(10), pp. 2379–2390 (2013)
  5. David Cholt, Progressive Hulls: Application on Biomedical Data, Proceedings of CESCG 2012: The 16th Central European Seminar on Computer Graphics (2012).
[J3]Nikos Platis, Theoharis Theoharis, Fast Ray-Tetrahedron Intersection Using Plücker Coordinates, journal of graphics tools, 8(4), σελ. 37–48 (2003).
  1. Esteban Rangel, Nan Li, Salman Habib, Tom Peterka, Ankit Agrawal, Wei-Keng Liao, Alok Choudhary, Parallel DTFE Surface Density Field Reconstruction, 2016 IEEE International Conference on Cluster Computing (CLUSTER), pp. 30–39 (2016).
  2. Jan Březina, Pavel Exner, Fast Intersection of Nonmatching Meshes Using Plücker Coordinates, Proceedings of ESCO 2016 (2016).
  3. John E Gillam, Georgios I Angelis, Steven R Meikle, List-mode image reconstruction for positron emission tomography using tetrahedral voxels, Physics in Medicine and Biology, 61, pp. N497, (2016).
  4. Petru Manescu, Hamid Ladjal, Joseph Azencot, Michael Beuve, Behzad Shariat, Motion compensation for PET image reconstruction using deformable tetrahedral meshes, Journal of Physics in Medicine and Biology, 60(24), pp. 9269 (2015).
  5. Jundong Tan, Zhuo Su, Yunliang Long, A Full 3-D GPU-based Beam-Tracing Method for Complex Indoor Environments Propagation Modeling, IEEE Transactions on Antennas and Propagation 63(6), pp. 2705 –2718 (2015).
  6. Christoph Böcklin, Dirk Baumann, Jürg Fröhlich, New approach for absolute fluence distribution calculations in Monte Carlo simulations of light propagation in turbid media, Journal of Applied Physics 115, 064905 (2014).
  7. Christoph Böcklin, Modelling light propagation in tissue, PhD Thesis, ETH Zurich (2014).
  8. Goretti Echegaray, Imanol Herrera, Iker Aguinaga, Carlos Buchart, Diego Borro, A Brain Surgery Simulator, IEEE Computer Graphics and Applications 34(3), pp. 12–18 (2014).
  9. Imanol Herrera, Carlos Buchart, Iker Aguinaga, Diego Borro, Study of a Ray Casting Technique for the Visualization of Deformable Volumes, IEEE Transactions on Visualization and Computer Graphics 20(11), pp. 1555–1565 (2014).
  10. Imanol Herrera, Volumetric Visualization Techniques of Rigid and Deformable Models for Surgery Simulation, PhD Thesis, University of Navarra (2013).
  11. Qianqian Fang, Comment on "A study on tetrahedron-based inhomogeneous Monte-Carlo optical simulation", Biomedical Optics Express 2(5), pp. 1258–1264 (2011).
  12. B.M. Smith, Robust Tracking and Advanced Geometry for Monte Carlo Radiation Transport, PhD Thesis, University of Winsconcin (2011).
  13. Haiou Shen, Ge Wang, A study on tetrahedron-based inhomogeneous Monte Carlo optical simulation, Biomedical Optics Express 2(1), pp. 44–57 (2011).
  14. Ahmad Hosney Awad Eid, Optimized Automatic Code Generation for Geometric Algebra Based Algorithms with Ray Tracing Application, PhD Thesis, Department of Electrical Engineering, Philadelphia University, Jordan (2010).
  15. Qianqian Fang, Mesh-based Monte Carlo method using fast ray-tracing in Plücker coordinates, Biomedical Optics Express 1(1), pp. 165–175 (2010).
  16. Gerd Marmitt, Heiko Friedrich, Philipp Slusallek, Efficient CPU-based Volume Ray Tracing Techniques, Computer Graphics Forum 27(6), pp. 1687–1709 (2008).
  17. Ares Lagae, Philip Dutré, Accelerating Ray Tracing using Constrained Tetrahedralizations, Computer Graphics Forum 27(4), pp. 1303–1312 (2008).
  18. Gerd Marmitt, Heiko Friedrich, Philipp Slusallek, Interactive Volume Rendering with Ray Tracing, Eurographics STAR – State of the Art Report (2006).
  19. Gerd Marmitt, Philipp Slusallek, Fast Ray Traversal of Tetrahedral and Hexahedral Meshes for Direct Volume Rendering, Proceedings of the joint Eurographics / IEEE-VGTC Symposium on Visualization, pp. 235–242 (2006).
  20. Gerd Marmitt, Heiko Friedrich, Philipp Slusallek, Recent Advancements in Ray tracing-based Volume Rendering Techniques, Proceedings of Vision, Modelling and Visualization – VMV (2005).
[J2]Antonis Ramfos, Ralph Busse, Nikos Platis, Peter Fankhauser, An Integration Framework for CORBA Objects, Journal of the Society for Design and Process Science, 3(1), pp. 27–41 (1999).
  1. Marko Rosić, Vlado Glavinić, Slavomir Stankov, Intelligent tutoring interoperability for the new web, Telecommunication Systems, 32(2–3), pp. 193–207 (2006).
  2. Luiz Fernando Bessa Seibel, Bio-AXS: An Architecture for Integrating Data Sources and Applications of Molecular Biology [Bio-AXS: Uma Arquitetura para Integração de Fontes de Dados e Aplicações de Biologia Molecular], PhD Thesis, Departamento de Informática, Pontifícia Universidade Católica do Rio de Janeiro (2000).
[J1]Christos Koukouvinos, Nikos Platis, Jennifer Seberry, Necessary and sufficient conditions for some two variable orthogonal designs in order 36, Congressus Numerantium, 114, pp. 129–139 (1996).
  1. Stelios D. Georgiou, New two-variable full orthogonal designs and related experiments with linear regression models, Statistics & Probability Letters, 77(1), pp. 25–31 (2007).
  2. Charles J. Colbourn, Jeffrey H. Dinitz (editors), The CRC Handbook of Combinatorial Designs, 1st ed., CRC Press (1996).

Publications in Refereed Conference Proceedings

[C3]George Lepouras, Akrivi Katifori, Costas Vassilakis, Angeliki Antoniou, Nikos Platis, Towards a Learning Analytics Platform for Supporting the Educational Process, The Fifth International Conference on Information, Intelligence, Systems and Applications – IISA, Crete (2014).
  1. Y. Vanessa Niet, V. G. Díaz, C. E. Montenegro, Academic decision making model for higher education institutions using learning analytics, 4th International Symposium on Computational and Business Intelligence (ISCBI), pp. 27–32 (2016).
  2. Ashwaq Al-Musharraf, Mona Alkhattabi, An Educational Data Mining Approach to Explore The Effect of Using Interactive Supporting Features in an LMS for Overall Performance Within an Online Learning Environment, International Journal of Computer Science and Network Security, 16(3) (2016).
  3. M. G. M. Mohan, S. K. Augustin, V. S. K. Roshni, A BigData approach for classification and prediction of student result using MapReduce, 2015 IEEE Recent Advances in Intelligent Computational Systems (RAICS), pp. 145–150 (2015).
  4. R. Suchithra, V. Vaidhehi, Nithya Easwaran Iyer, Survey of Learning Analytics based on Purpose and Techniques for Improving Student Performance, International Journal of Computer Applications, 111(1), pp. 22–26 (2015).
  5. Yuri Vanessa Nieto Acevedo, Carlos Enrique Montenegro Marín, Towards a Decision Support System based on Learning Analytics, Advances in Information Sciences and Service Sciences, 7(1), pp. 1–12 (2015).
  6. Yuri Vanessa Nieto Acevedo, Carlos Enrique Montenegro Marín, System Architecture Based on Learning Analytics to Educational Decision Makers Toolkit, Advances in Computer Science and Engineering, 13(2), pp. 89–105 (2014).
[C2]Nikos Platis, Theoharis Theoharis, Simplification of Vector Fields over Tetrahedral Meshes, Proceedings of Computer Graphics International 2004, Crete, pp. 174–181 (2004).
  1. Joshua A. Levine, Delaunay Methods for Approximating Geometric Domains, PhD Thesis, The Ohio State University (2009).
  2. Tamal K. Dey, Joshua A. Levine, Rephael Wenger, A Delaunay Simplification Algorithm for Vector Fields, Proceedings of 15th Pacific Graphics Conference (2007).
  3. Fabien Vivodtzev, Hiérarchisation et visualisation multirésolution de résultats issus de codes de simulation, PhD Thesis, Université Grenoble I - Joseph Fourier (2005).
[C1]Antonis Ramfos, Ralph Busse, Nikos Platis, Peter Fankhauser, CORBA-Based Data Integration Framework, Proceedings of the Third International Conference on Integrated Design and Process Technology (IDPT) – Vol. 2, International Workshop on Issues and Applications of Database Technology (IADT ’98), Berlin, Germany.
  1. Dalen Kambur, Mark Roantree, John Murphy, Using an Object Reference Approach to Distributed Updates, in Database and Expert Systems Applications (Lecture Notes in Computer Science, vol. 4653), pp. 182–191 (2007).